We show an integrated and multidisciplinary approach of continental research from field observations – mapping (geological and geophysical), sampling – laboratory determination of P-T and geochronological and mineral fabric data, geochemistry and analysis of geophysical signal (potential data – gravity and airborne magnetic) and paleomagnetism. This approach results in a large synthesis at the plate scale and allows to assess the mechanical behaviour and rheological properties of the lithosphere during collisional and accretionary processes.
In the interior of the Pangean system (future supercontinent) a new model of lower crustal flow is proposed allowing the redistribution of the lower plate underneath the upper plate at gigantic scales. We call this mechanism relamination and show how this material is coming to the asthenosphere and then relaminates beneath the Moho of the upper plate. We show how this material penetrates the upper plates in the form of translithospheric diapirs.
At the external boundary of the (Pangea) supercontinent, we show how the oceanic accreted systems are transformed into a mature continental lithosphere thereby becoming a stable continent at the contact of hot young/old cold oceans and continental margins.

published:07 Dec 2018

views:235

This resource is a 3-minute animated clip which combines images, diagrams, graphics and voice-over to explain what is meant by the mineral exploration method called seismic imaging or reflection seismology. It describes how scientists use technology to measure acoustic energy waves in the Earth to locate mineral, hydrocarbon and hot-rock resource deposits.

IMPORTANCE OF GEOLOGICAL SURVEY FOR BORE WELL DRILLING
Geophysical survey such as electrical resistivity sounding is the best approach. Surveyor sends electrical current into the ground and measures the resistance at various depth. From this measures of resistance or computed bulk resistivity, geophysicist can find out exactly what is below in the subsurface. Without geophysical survey, putting tube wells here and there will not yield groundwater in problematic area.
Drilling of a borewell with mear perception is not always giving water. Selection of deep bore well sites must be based on some scientific data by conducting proper examinations. Even some time these data will not give good result. Because the groundwater movement and potential is based on so many parameters. Some times all parameters can't be or are not in a situation to be studied. So it cause 5-10 % failure, but proper examination in borewell site selection will give 90-95% success.
I amPrivate Hydro-geologist, MSc.(Geo) From Osmania University,having 25 years of experience in Ground waterExploration field.
I am using Electrical Resistivity method Which is mostly used world wide.
Mostly I have worked at RangaReddy Dist, Hyderabad,Parts of Mahaboobnagar dist,Medak Dist,Nalgonda dist and part of the Karnataka .
WITH SUCCESSRATE @90-95%
SRINIVASULU
KACHIGUDA,HYDERABAD
9493401948
9290444400
geologistsrinivas@gmail.com
Read more: http://geologistsrinivaskandi.webnode.com//

published:30 Mar 2016

views:57838

This video is part of : Groundwater Spreadsheets for solving Groundwater Flow and PollutionProblems. Can be downloaded from:
https://sites.google.com/a/hidrogeocol.com.co/carlos_molano/Home

WHAT YOU DO: Use computer simulations to look at how the Earth's surface moves over time, compare this with information from satellites to better understand the earthquake cycle, and use it to create disaster response products and plans.
EDUCATION: Depending on whether you want to teach at a college, go into industry, or work for a research lab, your educational path will be slightly different. Start with an undergraduate degree, usually in Earth Science; you'll need at least a master's degree if you want to teach, and to be a tenured professor at a research institution, a PhD. Strong background in math, physics, Earth science, and solid mechanics is also important.
USEFUL SKILLS: Computer programming, writing (for writing grant proposals), communication, and leadership skills.
How to get in: Working in labs as a student, publishing papers (as a part of a professor's or student's research team), and going to scientific meetings to network are all ways to get yourself out there and meet people that can help you. If you're interested in research, you'll need your name on as many publications as possible by the time you start looking for a job.
CAREER PATH: In industry or a research lab, getting an internship while in school then pursuing a job at any lab or related company will get your foot in the door. In academic positions, you'll start out as a researcher with some teaching responsibilities; after years of research and experience, you can become a professor with full tenure.
PAYBACK: For an academic researcher with a master's degree and 3-5 years of experience, the average salary is about $69,000. With a PhD, you'll make more. If you work in industry, you can work with a bachelor's or a master's and make anywhere from $40,000-$50,000, depending on degree and experience.
DOWNSIDES: Securing funding can be a challenge. You spend a good part of your time writing proposals to make sure that your research is paid for, so that you can continue working on what you love.
FUTURE OF JOB: Teaching positions at universities are becoming increasingly competitive, as are positions at research labs. Jobs in industry (oil, mining, geotechnical) vary, depending on the market, but can also be competitive depending on the economy and region.
NETWORKING:
Professional Societies:
American Geophysical UnionSeismological Society of AmericaGeological Society of America
Other Resources:
Southern California Earthquake Center (has student internships and other educational resources)
Jet Propulsion Laboratory (look on Education page, has lots of resources)
NASA (education page has resources)
US Geological Survey (has a bunch of educational resources)
EarthScience departments at universities/colleges
Produced, shot and edited for the National Science Foundation by instructors from the Gigniks program.
-Ali Sanford (LACES12th grade)

EU2017: FutureScience -- Rebroadcast—only $29: https://www.electricuniverse.live
BruceLeybourne’s presentation will examine the geometries of Earth’s electrical stellar transformer circuits. Both statistical data and geometric correlations suggest geophysical relationships between lightning and earthquakes. The basic “Delta-Y” electrical circuit geometry of the tetrahedron “fire element” is expanded to a little known geometric form that unifies the five Platonic solids. The unique example of a diminished trigonal trapezohedron can provide a simplified roadmap to electric influences on earth from space, with implications for our understanding of inline/collapsed vortex relationships of energy flow in living organisms. The surprising conclusion is that the same specialized geometry applies to both the human heart and the clockwork geo-plasma physics of co-rotating double layer phenomenon so essential to Electric Universe models.
Bruce has a Masters degree in Geology from the University of Southern Mississippi. He is a Registered ProfessionalGeologist and is currently ResearchDirector of Institute for Advanced Studies in Climate Change (IASCC), while also working with Geostream Consulting LLC and Climate-Stat Inc. to improve geophysical-weather models. Bruce has spoken at many international conferences on the topic of geophysics and climate, authored and co-authored many papers, and is currently organizing a book to share his views on the nature of climate change. In addition, he has spent 10 years offshore performing gravity and magnetic survey work onboard seismic exploration vessels, in addition to seafloor mapping, oceanography, and geophysics with the Naval Oceanographic Office. http://www.iascc.org/
If you see a CC with this video, it means that subtitles are available. To find out which ones, click on the GearIcon in the lower right area of the video box and click on “subtitles” in the drop-down box. Then click on the subtitle that you would like.
Become a Producer through the PATREON Rewards program -- https://www.patreon.com/tboltsproject
Subscribe to Thunderbolts Update newsletter: http://eepurl.com/ETy41
The ThunderboltsProjectHome: http://www.thunderbolts.info
EssentialGuide to the Electric Universe: http://www.thunderbolts.info/wp/eg-contents/
Facebook: http://www.facebook.com/thunderboltsproject
Twitter: @tboltsproject
Electric Universe by Wal Thornhill: http://www.holoscience.com/wp/
Electric Universe T-shirts and Gifts: http://stickmanonstone.com/
Copyrighted materials are being used according to the Multimedia Fair Use Guidelines.
The ideas expressed in videos presented on The Thunderbolts Project YouTube Channel do not necessarily express the views of T-Bolts GroupInc or The Thunderbolts Project(TM).

Background and release

After the success of her debut album, Let Go (2002), Lavigne released her second album, Under My Skin (2004), which debuted at number one in more than ten countries, went platinum within one month, and further established Lavigne as a pop icon. Later, a song that was co-written by Lavigne and ultimately cut from the final track list -- "Breakaway"—was later given to Kelly Clarkson, who used it as the title track and lead-off single for her Grammy-winning second album. In July 2006, Lavigne married Sum 41's Deryck Whibley and spent most of the year working on her third album, enlisting blink-182 drummer Travis Barker to play drums, and cherry-picking a variety of producers (including her husband) to helm the recording sessions. Lavigne described the album as "really fast, fun, young, bratty, aggressive, confident, cocky in a playful way."

Hot (Inna song)

"Hot" is a song by Romanian dance/pop vocalist Inna extracted from her debut studio album Hot 2009. Written and produced by Sebastian Barac, Radu Bolfea and Marcel Botezan of Play & Win, "Hot" was released late as the lead single from her debut record. The song is an uptempo electro house song, with it containing elements of trance music. Lyrically, it tells a story of how strong a connection between two lovers can become. Contemporary critics received "Hot" very well, with reviewers complimenting its beats, simplicity and effectiveness.

The track was a commercial success, reaching the top-ten in Belgium, Spain, Hungary, Czech Republic, France, Netherlands and Romania. "Hot" has been accompanied by two European club-themed official music video versions, with the first being released on 10 November 2008. Inna has promoted the song at various gigs across Europe and has also performed it on the 2009 Eska Music Awards, Legendario Ice Experience, Loop Live and the Sopot Hit Festival in Poland.

WQHT

WQHT (97.1 FM) – also known as Hot 97 – is an American radio station in New York City under the corporate ownership of Emmis Communications. The station broadcasts on 97.1MHz FM. Despite being billed as a Rhythmic CHR station on Mediabase and Nielsen BDS, WQHT primarily plays mainstream urban hits, with a few pop-leaning titles on occasion. It is one of two flagship radio properties of Emmis, in addition to co-owned KPWR ("Power 106") in Los Angeles.

History

WNBC-FM and variants

The history of the 97.1 frequency goes back to 1949, when experimental station W2XWG came on the air in 1940 on 42.6MHz. That station became W51NY when it moved to 45.1MHz. On September 22, 1944, W51NY began commercial operations as WEAF-FM. After several frequency and call letters changes, WNBC-FM was established at 97.1 by 1949. It usually simulcastWNBC's AM programming. In 1954, it changed its call letters to WRCA-FM (reflecting NBC's then-parent company, RCA), but reverted to WNBC-FM in 1960.

Points of the compass

The points of the compass are points on a compass, specifically on the compass rose, marking divisions of the four cardinal directions: North, South, East, West. The number of points may be only the 4 cardinal points, or the 8 principal points adding the intercardinal (or ordinal) directions northeast (NE), southeast (SE), southwest (SW), and northwest (NW). In meteorological usage further intermediate points are added to give the sixteen points of a wind compass. Finally, at the most complete in European tradition, are found the full thirty-two points of the mariner's compass. In ancient China 24 points of the compass were used.

In the mariner's exercise of boxing the compass, all thirty-two points of the compass are named in clockwise order. The names of intermediate points are formed by the initials of the cardinal directions and their intermediate ordinal directions, and are very handy to refer to a heading (or course or azimuth) in a general or colloquial fashion, without having to resort to computing or recalling degrees. For most applications, the minor points have been superseded by degrees measured clockwise from North.

List of sub regions used in the London Plan

Greater London is divided into 5 sub regions for the purposes of the London Plan. The boundaries of these areas were amended in 2008 and 2011 and their role in the implementation of the London Plan has varied with each iteration.

From 2004 to 2008, the sub regions were initially the same as the Learning and Skills Council areas set up in 1999. These 2004–2008 sub regions each had a Sub-Regional Development Framework. The sub regions were revised in February 2008 as part of the Further Alterations to the London Plan. The 2008–2011 sub regions, each had its own Sub Regional Implementation Framework. In 2011, the sub regions were revised again. The 2011 sub regions are to be used for statutory monitoring, engagement and resource allocation.

Electric Universe

Electric Universe is a psychedelic trance project from Germany formed by Boris Blenn and Michael Dressler in 1991. Their first EP release, Solar Energy was an instant hit with the underground trance scene and is often credited with putting the Spirit Zone Recordings label at the forefront of psychedelic trance early on. According to The Sofia Echo, they were "hailed in the 1990s as one of the top psychedelic trance projects to come out of Germany".

History

The Electric Universe project was founded in 1991 by Boris Blenn and Michael Dressler in Hamburg, Germany. After being inspired by the first big Voov Experience in Sprötze, the first Psy Trance orientated tracks were produced, with just 5 pieces of equipment. These were two synthesizers, one sampler, a mixing desk and an Atari 1080. Some of the tracks found their way into the hands of DJ Antaro, who had just started his record label Spirit Zone. He liked the stuff and decided to release the Electric Universe Solar Energy maxi single as the second release on his label. It turned out to be a big hit and set the ground for the first album One Love in 1994.

Center for Lithospheric Research, Czech Geological Survey

We show an integrated and multidisciplinary approach of continental research from field observations – mapping (geological and geophysical), sampling – laboratory determination of P-T and geochronological and mineral fabric data, geochemistry and analysis of geophysical signal (potential data – gravity and airborne magnetic) and paleomagnetism. This approach results in a large synthesis at the plate scale and allows to assess the mechanical behaviour and rheological properties of the lithosphere during collisional and accretionary processes.
In the interior of the Pangean system (future supercontinent) a new model of lower crustal flow is proposed allowing the redistribution of the lower plate underneath the upper plate at gigantic scales. We call this mechanism relamination and show how this material is coming to the asthenosphere and then relaminates beneath the Moho of the upper plate. We show how this material penetrates the upper plates in the form of translithospheric diapirs.
At the external boundary of the (Pangea) supercontinent, we show how the oceanic accreted systems are transformed into a mature continental lithosphere thereby becoming a stable continent at the contact of hot young/old cold oceans and continental margins.

2:59

Seismic Imaging Animation

Seismic Imaging Animation

Seismic Imaging Animation

This resource is a 3-minute animated clip which combines images, diagrams, graphics and voice-over to explain what is meant by the mineral exploration method called seismic imaging or reflection seismology. It describes how scientists use technology to measure acoustic energy waves in the Earth to locate mineral, hydrocarbon and hot-rock resource deposits.

hydro geological survey to locate ground water for bore well

IMPORTANCE OF GEOLOGICAL SURVEY FOR BORE WELL DRILLING
Geophysical survey such as electrical resistivity sounding is the best approach. Surveyor sends electrical current into the ground and measures the resistance at various depth. From this measures of resistance or computed bulk resistivity, geophysicist can find out exactly what is below in the subsurface. Without geophysical survey, putting tube wells here and there will not yield groundwater in problematic area.
Drilling of a borewell with mear perception is not always giving water. Selection of deep bore well sites must be based on some scientific data by conducting proper examinations. Even some time these data will not give good result. Because the groundwater movement and potential is based on so many parameters. Some times all parameters can't be or are not in a situation to be studied. So it cause 5-10 % failure, but proper examination in borewell site selection will give 90-95% success.
I amPrivate Hydro-geologist, MSc.(Geo) From Osmania University,having 25 years of experience in Ground waterExploration field.
I am using Electrical Resistivity method Which is mostly used world wide.
Mostly I have worked at RangaReddy Dist, Hyderabad,Parts of Mahaboobnagar dist,Medak Dist,Nalgonda dist and part of the Karnataka .
WITH SUCCESSRATE @90-95%
SRINIVASULU
KACHIGUDA,HYDERABAD
9493401948
9290444400
geologistsrinivas@gmail.com
Read more: http://geologistsrinivaskandi.webnode.com//

4:30

SPREADSHEET FOR INTERPRETATION OF SCHLUMBERGER VES DATA

SPREADSHEET FOR INTERPRETATION OF SCHLUMBERGER VES DATA

SPREADSHEET FOR INTERPRETATION OF SCHLUMBERGER VES DATA

This video is part of : Groundwater Spreadsheets for solving Groundwater Flow and PollutionProblems. Can be downloaded from:
https://sites.google.com/a/hidrogeocol.com.co/carlos_molano/Home

Hydrographic Survey with WASSP Mutlibeam Sonar

Seismic Geophysicist

WHAT YOU DO: Use computer simulations to look at how the Earth's surface moves over time, compare this with information from satellites to better understand the earthquake cycle, and use it to create disaster response products and plans.
EDUCATION: Depending on whether you want to teach at a college, go into industry, or work for a research lab, your educational path will be slightly different. Start with an undergraduate degree, usually in Earth Science; you'll need at least a master's degree if you want to teach, and to be a tenured professor at a research institution, a PhD. Strong background in math, physics, Earth science, and solid mechanics is also important.
USEFUL SKILLS: Computer programming, writing (for writing grant proposals), communication, and leadership skills.
How to get in: Working in labs as a student, publishing papers (as a part of a professor's or student's research team), and going to scientific meetings to network are all ways to get yourself out there and meet people that can help you. If you're interested in research, you'll need your name on as many publications as possible by the time you start looking for a job.
CAREER PATH: In industry or a research lab, getting an internship while in school then pursuing a job at any lab or related company will get your foot in the door. In academic positions, you'll start out as a researcher with some teaching responsibilities; after years of research and experience, you can become a professor with full tenure.
PAYBACK: For an academic researcher with a master's degree and 3-5 years of experience, the average salary is about $69,000. With a PhD, you'll make more. If you work in industry, you can work with a bachelor's or a master's and make anywhere from $40,000-$50,000, depending on degree and experience.
DOWNSIDES: Securing funding can be a challenge. You spend a good part of your time writing proposals to make sure that your research is paid for, so that you can continue working on what you love.
FUTURE OF JOB: Teaching positions at universities are becoming increasingly competitive, as are positions at research labs. Jobs in industry (oil, mining, geotechnical) vary, depending on the market, but can also be competitive depending on the economy and region.
NETWORKING:
Professional Societies:
American Geophysical UnionSeismological Society of AmericaGeological Society of America
Other Resources:
Southern California Earthquake Center (has student internships and other educational resources)
Jet Propulsion Laboratory (look on Education page, has lots of resources)
NASA (education page has resources)
US Geological Survey (has a bunch of educational resources)
EarthScience departments at universities/colleges
Produced, shot and edited for the National Science Foundation by instructors from the Gigniks program.
-Ali Sanford (LACES12th grade)

3:04

geophysics electrical resistivity survey in archaeological site in west bank of luxor

geophysics electrical resistivity survey in archaeological site in west bank of luxor

geophysics electrical resistivity survey in archaeological site in west bank of luxor

EU2017: FutureScience -- Rebroadcast—only $29: https://www.electricuniverse.live
BruceLeybourne’s presentation will examine the geometries of Earth’s electrical stellar transformer circuits. Both statistical data and geometric correlations suggest geophysical relationships between lightning and earthquakes. The basic “Delta-Y” electrical circuit geometry of the tetrahedron “fire element” is expanded to a little known geometric form that unifies the five Platonic solids. The unique example of a diminished trigonal trapezohedron can provide a simplified roadmap to electric influences on earth from space, with implications for our understanding of inline/collapsed vortex relationships of energy flow in living organisms. The surprising conclusion is that the same specialized geometry applies to both the human heart and the clockwork geo-plasma physics of co-rotating double layer phenomenon so essential to Electric Universe models.
Bruce has a Masters degree in Geology from the University of Southern Mississippi. He is a Registered ProfessionalGeologist and is currently ResearchDirector of Institute for Advanced Studies in Climate Change (IASCC), while also working with Geostream Consulting LLC and Climate-Stat Inc. to improve geophysical-weather models. Bruce has spoken at many international conferences on the topic of geophysics and climate, authored and co-authored many papers, and is currently organizing a book to share his views on the nature of climate change. In addition, he has spent 10 years offshore performing gravity and magnetic survey work onboard seismic exploration vessels, in addition to seafloor mapping, oceanography, and geophysics with the Naval Oceanographic Office. http://www.iascc.org/
If you see a CC with this video, it means that subtitles are available. To find out which ones, click on the GearIcon in the lower right area of the video box and click on “subtitles” in the drop-down box. Then click on the subtitle that you would like.
Become a Producer through the PATREON Rewards program -- https://www.patreon.com/tboltsproject
Subscribe to Thunderbolts Update newsletter: http://eepurl.com/ETy41
The ThunderboltsProjectHome: http://www.thunderbolts.info
EssentialGuide to the Electric Universe: http://www.thunderbolts.info/wp/eg-contents/
Facebook: http://www.facebook.com/thunderboltsproject
Twitter: @tboltsproject
Electric Universe by Wal Thornhill: http://www.holoscience.com/wp/
Electric Universe T-shirts and Gifts: http://stickmanonstone.com/
Copyrighted materials are being used according to the Multimedia Fair Use Guidelines.
The ideas expressed in videos presented on The Thunderbolts Project YouTube Channel do not necessarily express the views of T-Bolts GroupInc or The Thunderbolts Project(TM).

0:31

Seismic Surveying.mp4

Seismic Surveying.mp4

Seismic Surveying.mp4

This short animation was created for an exhibit in Fort Worth Texas. It shows how seismic vibrato trucks use vibrations to explore miles under the earth for oil. The animation was created in Modo 401, After Effects and Premier.

Center for Lithospheric Research, Czech Geological Survey

We show an integrated and multidisciplinary approach of continental research from field observations – mapping (geological and geophysical), sampling – laboratory determination of P-T and geochronological and mineral fabric data, geochemistry and analysis of geophysical signal (potential data – gravity and airborne magnetic) and paleomagnetism. This approach results in a large synthesis at the plate scale and allows to assess the mechanical behaviour and rheological properties of the lithosphere during collisional and accretionary processes.
In the interior of the Pangean system (future supercontinent) a new model of lower crustal flow is proposed allowing the redistribution of the lower plate underneath the upper plate at gigantic scales. We call this mechanism relamination and show how...

published: 07 Dec 2018

Seismic Imaging Animation

This resource is a 3-minute animated clip which combines images, diagrams, graphics and voice-over to explain what is meant by the mineral exploration method called seismic imaging or reflection seismology. It describes how scientists use technology to measure acoustic energy waves in the Earth to locate mineral, hydrocarbon and hot-rock resource deposits.

hydro geological survey to locate ground water for bore well

IMPORTANCE OF GEOLOGICAL SURVEY FOR BORE WELL DRILLING
Geophysical survey such as electrical resistivity sounding is the best approach. Surveyor sends electrical current into the ground and measures the resistance at various depth. From this measures of resistance or computed bulk resistivity, geophysicist can find out exactly what is below in the subsurface. Without geophysical survey, putting tube wells here and there will not yield groundwater in problematic area.
Drilling of a borewell with mear perception is not always giving water. Selection of deep bore well sites must be based on some scientific data by conducting proper examinations. Even some time these data will not give good result. Because the groundwater movement and potential is based on so many parameters. Some...

published: 30 Mar 2016

SPREADSHEET FOR INTERPRETATION OF SCHLUMBERGER VES DATA

This video is part of : Groundwater Spreadsheets for solving Groundwater Flow and PollutionProblems. Can be downloaded from:
https://sites.google.com/a/hidrogeocol.com.co/carlos_molano/Home

published: 03 Aug 2011

Hydrographic Survey with WASSP Mutlibeam Sonar

Seismic Geophysicist

WHAT YOU DO: Use computer simulations to look at how the Earth's surface moves over time, compare this with information from satellites to better understand the earthquake cycle, and use it to create disaster response products and plans.
EDUCATION: Depending on whether you want to teach at a college, go into industry, or work for a research lab, your educational path will be slightly different. Start with an undergraduate degree, usually in Earth Science; you'll need at least a master's degree if you want to teach, and to be a tenured professor at a research institution, a PhD. Strong background in math, physics, Earth science, and solid mechanics is also important.
USEFUL SKILLS: Computer programming, writing (for writing grant proposals), communication, and leadership skills.
How to g...

published: 11 Feb 2014

geophysics electrical resistivity survey in archaeological site in west bank of luxor

EU2017: FutureScience -- Rebroadcast—only $29: https://www.electricuniverse.live
BruceLeybourne’s presentation will examine the geometries of Earth’s electrical stellar transformer circuits. Both statistical data and geometric correlations suggest geophysical relationships between lightning and earthquakes. The basic “Delta-Y” electrical circuit geometry of the tetrahedron “fire element” is expanded to a little known geometric form that unifies the five Platonic solids. The unique example of a diminished trigonal trapezohedron can provide a simplified roadmap to electric influences on earth from space, with implications for our understanding of inline/collapsed vortex relationships of energy flow in living organisms. The surprising conclusion is that the same specialized geometry applie...

published: 08 Jul 2018

Seismic Surveying.mp4

This short animation was created for an exhibit in Fort Worth Texas. It shows how seismic vibrato trucks use vibrations to explore miles under the earth for oil. The animation was created in Modo 401, After Effects and Premier.

Center for Lithospheric Research, Czech Geological Survey

We show an integrated and multidisciplinary approach of continental research from field observations – mapping (geological and geophysical), sampling – laborato...

We show an integrated and multidisciplinary approach of continental research from field observations – mapping (geological and geophysical), sampling – laboratory determination of P-T and geochronological and mineral fabric data, geochemistry and analysis of geophysical signal (potential data – gravity and airborne magnetic) and paleomagnetism. This approach results in a large synthesis at the plate scale and allows to assess the mechanical behaviour and rheological properties of the lithosphere during collisional and accretionary processes.
In the interior of the Pangean system (future supercontinent) a new model of lower crustal flow is proposed allowing the redistribution of the lower plate underneath the upper plate at gigantic scales. We call this mechanism relamination and show how this material is coming to the asthenosphere and then relaminates beneath the Moho of the upper plate. We show how this material penetrates the upper plates in the form of translithospheric diapirs.
At the external boundary of the (Pangea) supercontinent, we show how the oceanic accreted systems are transformed into a mature continental lithosphere thereby becoming a stable continent at the contact of hot young/old cold oceans and continental margins.

We show an integrated and multidisciplinary approach of continental research from field observations – mapping (geological and geophysical), sampling – laboratory determination of P-T and geochronological and mineral fabric data, geochemistry and analysis of geophysical signal (potential data – gravity and airborne magnetic) and paleomagnetism. This approach results in a large synthesis at the plate scale and allows to assess the mechanical behaviour and rheological properties of the lithosphere during collisional and accretionary processes.
In the interior of the Pangean system (future supercontinent) a new model of lower crustal flow is proposed allowing the redistribution of the lower plate underneath the upper plate at gigantic scales. We call this mechanism relamination and show how this material is coming to the asthenosphere and then relaminates beneath the Moho of the upper plate. We show how this material penetrates the upper plates in the form of translithospheric diapirs.
At the external boundary of the (Pangea) supercontinent, we show how the oceanic accreted systems are transformed into a mature continental lithosphere thereby becoming a stable continent at the contact of hot young/old cold oceans and continental margins.

Seismic Imaging Animation

This resource is a 3-minute animated clip which combines images, diagrams, graphics and voice-over to explain what is meant by the mineral exploration method ca...

This resource is a 3-minute animated clip which combines images, diagrams, graphics and voice-over to explain what is meant by the mineral exploration method called seismic imaging or reflection seismology. It describes how scientists use technology to measure acoustic energy waves in the Earth to locate mineral, hydrocarbon and hot-rock resource deposits.

This resource is a 3-minute animated clip which combines images, diagrams, graphics and voice-over to explain what is meant by the mineral exploration method called seismic imaging or reflection seismology. It describes how scientists use technology to measure acoustic energy waves in the Earth to locate mineral, hydrocarbon and hot-rock resource deposits.

hydro geological survey to locate ground water for bore well

IMPORTANCE OF GEOLOGICAL SURVEY FOR BORE WELL DRILLING
Geophysical survey such as electrical resistivity sounding is the best approach. Surveyor sends electric...

IMPORTANCE OF GEOLOGICAL SURVEY FOR BORE WELL DRILLING
Geophysical survey such as electrical resistivity sounding is the best approach. Surveyor sends electrical current into the ground and measures the resistance at various depth. From this measures of resistance or computed bulk resistivity, geophysicist can find out exactly what is below in the subsurface. Without geophysical survey, putting tube wells here and there will not yield groundwater in problematic area.
Drilling of a borewell with mear perception is not always giving water. Selection of deep bore well sites must be based on some scientific data by conducting proper examinations. Even some time these data will not give good result. Because the groundwater movement and potential is based on so many parameters. Some times all parameters can't be or are not in a situation to be studied. So it cause 5-10 % failure, but proper examination in borewell site selection will give 90-95% success.
I amPrivate Hydro-geologist, MSc.(Geo) From Osmania University,having 25 years of experience in Ground waterExploration field.
I am using Electrical Resistivity method Which is mostly used world wide.
Mostly I have worked at RangaReddy Dist, Hyderabad,Parts of Mahaboobnagar dist,Medak Dist,Nalgonda dist and part of the Karnataka .
WITH SUCCESSRATE @90-95%
SRINIVASULU
KACHIGUDA,HYDERABAD
9493401948
9290444400
geologistsrinivas@gmail.com
Read more: http://geologistsrinivaskandi.webnode.com//

IMPORTANCE OF GEOLOGICAL SURVEY FOR BORE WELL DRILLING
Geophysical survey such as electrical resistivity sounding is the best approach. Surveyor sends electrical current into the ground and measures the resistance at various depth. From this measures of resistance or computed bulk resistivity, geophysicist can find out exactly what is below in the subsurface. Without geophysical survey, putting tube wells here and there will not yield groundwater in problematic area.
Drilling of a borewell with mear perception is not always giving water. Selection of deep bore well sites must be based on some scientific data by conducting proper examinations. Even some time these data will not give good result. Because the groundwater movement and potential is based on so many parameters. Some times all parameters can't be or are not in a situation to be studied. So it cause 5-10 % failure, but proper examination in borewell site selection will give 90-95% success.
I amPrivate Hydro-geologist, MSc.(Geo) From Osmania University,having 25 years of experience in Ground waterExploration field.
I am using Electrical Resistivity method Which is mostly used world wide.
Mostly I have worked at RangaReddy Dist, Hyderabad,Parts of Mahaboobnagar dist,Medak Dist,Nalgonda dist and part of the Karnataka .
WITH SUCCESSRATE @90-95%
SRINIVASULU
KACHIGUDA,HYDERABAD
9493401948
9290444400
geologistsrinivas@gmail.com
Read more: http://geologistsrinivaskandi.webnode.com//

Seismic Geophysicist

WHAT YOU DO: Use computer simulations to look at how the Earth's surface moves over time, compare this with information from satellites to better understand the...

WHAT YOU DO: Use computer simulations to look at how the Earth's surface moves over time, compare this with information from satellites to better understand the earthquake cycle, and use it to create disaster response products and plans.
EDUCATION: Depending on whether you want to teach at a college, go into industry, or work for a research lab, your educational path will be slightly different. Start with an undergraduate degree, usually in Earth Science; you'll need at least a master's degree if you want to teach, and to be a tenured professor at a research institution, a PhD. Strong background in math, physics, Earth science, and solid mechanics is also important.
USEFUL SKILLS: Computer programming, writing (for writing grant proposals), communication, and leadership skills.
How to get in: Working in labs as a student, publishing papers (as a part of a professor's or student's research team), and going to scientific meetings to network are all ways to get yourself out there and meet people that can help you. If you're interested in research, you'll need your name on as many publications as possible by the time you start looking for a job.
CAREER PATH: In industry or a research lab, getting an internship while in school then pursuing a job at any lab or related company will get your foot in the door. In academic positions, you'll start out as a researcher with some teaching responsibilities; after years of research and experience, you can become a professor with full tenure.
PAYBACK: For an academic researcher with a master's degree and 3-5 years of experience, the average salary is about $69,000. With a PhD, you'll make more. If you work in industry, you can work with a bachelor's or a master's and make anywhere from $40,000-$50,000, depending on degree and experience.
DOWNSIDES: Securing funding can be a challenge. You spend a good part of your time writing proposals to make sure that your research is paid for, so that you can continue working on what you love.
FUTURE OF JOB: Teaching positions at universities are becoming increasingly competitive, as are positions at research labs. Jobs in industry (oil, mining, geotechnical) vary, depending on the market, but can also be competitive depending on the economy and region.
NETWORKING:
Professional Societies:
American Geophysical UnionSeismological Society of AmericaGeological Society of America
Other Resources:
Southern California Earthquake Center (has student internships and other educational resources)
Jet Propulsion Laboratory (look on Education page, has lots of resources)
NASA (education page has resources)
US Geological Survey (has a bunch of educational resources)
EarthScience departments at universities/colleges
Produced, shot and edited for the National Science Foundation by instructors from the Gigniks program.
-Ali Sanford (LACES12th grade)

WHAT YOU DO: Use computer simulations to look at how the Earth's surface moves over time, compare this with information from satellites to better understand the earthquake cycle, and use it to create disaster response products and plans.
EDUCATION: Depending on whether you want to teach at a college, go into industry, or work for a research lab, your educational path will be slightly different. Start with an undergraduate degree, usually in Earth Science; you'll need at least a master's degree if you want to teach, and to be a tenured professor at a research institution, a PhD. Strong background in math, physics, Earth science, and solid mechanics is also important.
USEFUL SKILLS: Computer programming, writing (for writing grant proposals), communication, and leadership skills.
How to get in: Working in labs as a student, publishing papers (as a part of a professor's or student's research team), and going to scientific meetings to network are all ways to get yourself out there and meet people that can help you. If you're interested in research, you'll need your name on as many publications as possible by the time you start looking for a job.
CAREER PATH: In industry or a research lab, getting an internship while in school then pursuing a job at any lab or related company will get your foot in the door. In academic positions, you'll start out as a researcher with some teaching responsibilities; after years of research and experience, you can become a professor with full tenure.
PAYBACK: For an academic researcher with a master's degree and 3-5 years of experience, the average salary is about $69,000. With a PhD, you'll make more. If you work in industry, you can work with a bachelor's or a master's and make anywhere from $40,000-$50,000, depending on degree and experience.
DOWNSIDES: Securing funding can be a challenge. You spend a good part of your time writing proposals to make sure that your research is paid for, so that you can continue working on what you love.
FUTURE OF JOB: Teaching positions at universities are becoming increasingly competitive, as are positions at research labs. Jobs in industry (oil, mining, geotechnical) vary, depending on the market, but can also be competitive depending on the economy and region.
NETWORKING:
Professional Societies:
American Geophysical UnionSeismological Society of AmericaGeological Society of America
Other Resources:
Southern California Earthquake Center (has student internships and other educational resources)
Jet Propulsion Laboratory (look on Education page, has lots of resources)
NASA (education page has resources)
US Geological Survey (has a bunch of educational resources)
EarthScience departments at universities/colleges
Produced, shot and edited for the National Science Foundation by instructors from the Gigniks program.
-Ali Sanford (LACES12th grade)

EU2017: FutureScience -- Rebroadcast—only $29: https://www.electricuniverse.live
BruceLeybourne’s presentation will examine the geometries of Earth’s electrical stellar transformer circuits. Both statistical data and geometric correlations suggest geophysical relationships between lightning and earthquakes. The basic “Delta-Y” electrical circuit geometry of the tetrahedron “fire element” is expanded to a little known geometric form that unifies the five Platonic solids. The unique example of a diminished trigonal trapezohedron can provide a simplified roadmap to electric influences on earth from space, with implications for our understanding of inline/collapsed vortex relationships of energy flow in living organisms. The surprising conclusion is that the same specialized geometry applies to both the human heart and the clockwork geo-plasma physics of co-rotating double layer phenomenon so essential to Electric Universe models.
Bruce has a Masters degree in Geology from the University of Southern Mississippi. He is a Registered ProfessionalGeologist and is currently ResearchDirector of Institute for Advanced Studies in Climate Change (IASCC), while also working with Geostream Consulting LLC and Climate-Stat Inc. to improve geophysical-weather models. Bruce has spoken at many international conferences on the topic of geophysics and climate, authored and co-authored many papers, and is currently organizing a book to share his views on the nature of climate change. In addition, he has spent 10 years offshore performing gravity and magnetic survey work onboard seismic exploration vessels, in addition to seafloor mapping, oceanography, and geophysics with the Naval Oceanographic Office. http://www.iascc.org/
If you see a CC with this video, it means that subtitles are available. To find out which ones, click on the GearIcon in the lower right area of the video box and click on “subtitles” in the drop-down box. Then click on the subtitle that you would like.
Become a Producer through the PATREON Rewards program -- https://www.patreon.com/tboltsproject
Subscribe to Thunderbolts Update newsletter: http://eepurl.com/ETy41
The ThunderboltsProjectHome: http://www.thunderbolts.info
EssentialGuide to the Electric Universe: http://www.thunderbolts.info/wp/eg-contents/
Facebook: http://www.facebook.com/thunderboltsproject
Twitter: @tboltsproject
Electric Universe by Wal Thornhill: http://www.holoscience.com/wp/
Electric Universe T-shirts and Gifts: http://stickmanonstone.com/
Copyrighted materials are being used according to the Multimedia Fair Use Guidelines.
The ideas expressed in videos presented on The Thunderbolts Project YouTube Channel do not necessarily express the views of T-Bolts GroupInc or The Thunderbolts Project(TM).

EU2017: FutureScience -- Rebroadcast—only $29: https://www.electricuniverse.live
BruceLeybourne’s presentation will examine the geometries of Earth’s electrical stellar transformer circuits. Both statistical data and geometric correlations suggest geophysical relationships between lightning and earthquakes. The basic “Delta-Y” electrical circuit geometry of the tetrahedron “fire element” is expanded to a little known geometric form that unifies the five Platonic solids. The unique example of a diminished trigonal trapezohedron can provide a simplified roadmap to electric influences on earth from space, with implications for our understanding of inline/collapsed vortex relationships of energy flow in living organisms. The surprising conclusion is that the same specialized geometry applies to both the human heart and the clockwork geo-plasma physics of co-rotating double layer phenomenon so essential to Electric Universe models.
Bruce has a Masters degree in Geology from the University of Southern Mississippi. He is a Registered ProfessionalGeologist and is currently ResearchDirector of Institute for Advanced Studies in Climate Change (IASCC), while also working with Geostream Consulting LLC and Climate-Stat Inc. to improve geophysical-weather models. Bruce has spoken at many international conferences on the topic of geophysics and climate, authored and co-authored many papers, and is currently organizing a book to share his views on the nature of climate change. In addition, he has spent 10 years offshore performing gravity and magnetic survey work onboard seismic exploration vessels, in addition to seafloor mapping, oceanography, and geophysics with the Naval Oceanographic Office. http://www.iascc.org/
If you see a CC with this video, it means that subtitles are available. To find out which ones, click on the GearIcon in the lower right area of the video box and click on “subtitles” in the drop-down box. Then click on the subtitle that you would like.
Become a Producer through the PATREON Rewards program -- https://www.patreon.com/tboltsproject
Subscribe to Thunderbolts Update newsletter: http://eepurl.com/ETy41
The ThunderboltsProjectHome: http://www.thunderbolts.info
EssentialGuide to the Electric Universe: http://www.thunderbolts.info/wp/eg-contents/
Facebook: http://www.facebook.com/thunderboltsproject
Twitter: @tboltsproject
Electric Universe by Wal Thornhill: http://www.holoscience.com/wp/
Electric Universe T-shirts and Gifts: http://stickmanonstone.com/
Copyrighted materials are being used according to the Multimedia Fair Use Guidelines.
The ideas expressed in videos presented on The Thunderbolts Project YouTube Channel do not necessarily express the views of T-Bolts GroupInc or The Thunderbolts Project(TM).

Seismic Surveying.mp4

This short animation was created for an exhibit in Fort Worth Texas. It shows how seismic vibrato trucks use vibrations to explore miles under the earth for oil...

This short animation was created for an exhibit in Fort Worth Texas. It shows how seismic vibrato trucks use vibrations to explore miles under the earth for oil. The animation was created in Modo 401, After Effects and Premier.

This short animation was created for an exhibit in Fort Worth Texas. It shows how seismic vibrato trucks use vibrations to explore miles under the earth for oil. The animation was created in Modo 401, After Effects and Premier.

Center for Lithospheric Research, Czech Geological Survey

We show an integrated and multidisciplinary approach of continental research from field observations – mapping (geological and geophysical), sampling – laboratory determination of P-T and geochronological and mineral fabric data, geochemistry and analysis of geophysical signal (potential data – gravity and airborne magnetic) and paleomagnetism. This approach results in a large synthesis at the plate scale and allows to assess the mechanical behaviour and rheological properties of the lithosphere during collisional and accretionary processes.
In the interior of the Pangean system (future supercontinent) a new model of lower crustal flow is proposed allowing the redistribution of the lower plate underneath the upper plate at gigantic scales. We call this mechanism relamination and show how this material is coming to the asthenosphere and then relaminates beneath the Moho of the upper plate. We show how this material penetrates the upper plates in the form of translithospheric diapirs.
At the external boundary of the (Pangea) supercontinent, we show how the oceanic accreted systems are transformed into a mature continental lithosphere thereby becoming a stable continent at the contact of hot young/old cold oceans and continental margins.

Seismic Imaging Animation

This resource is a 3-minute animated clip which combines images, diagrams, graphics and voice-over to explain what is meant by the mineral exploration method called seismic imaging or reflection seismology. It describes how scientists use technology to measure acoustic energy waves in the Earth to locate mineral, hydrocarbon and hot-rock resource deposits.

hydro geological survey to locate ground water for bore well

IMPORTANCE OF GEOLOGICAL SURVEY FOR BORE WELL DRILLING
Geophysical survey such as electrical resistivity sounding is the best approach. Surveyor sends electrical current into the ground and measures the resistance at various depth. From this measures of resistance or computed bulk resistivity, geophysicist can find out exactly what is below in the subsurface. Without geophysical survey, putting tube wells here and there will not yield groundwater in problematic area.
Drilling of a borewell with mear perception is not always giving water. Selection of deep bore well sites must be based on some scientific data by conducting proper examinations. Even some time these data will not give good result. Because the groundwater movement and potential is based on so many parameters. Some times all parameters can't be or are not in a situation to be studied. So it cause 5-10 % failure, but proper examination in borewell site selection will give 90-95% success.
I amPrivate Hydro-geologist, MSc.(Geo) From Osmania University,having 25 years of experience in Ground waterExploration field.
I am using Electrical Resistivity method Which is mostly used world wide.
Mostly I have worked at RangaReddy Dist, Hyderabad,Parts of Mahaboobnagar dist,Medak Dist,Nalgonda dist and part of the Karnataka .
WITH SUCCESSRATE @90-95%
SRINIVASULU
KACHIGUDA,HYDERABAD
9493401948
9290444400
geologistsrinivas@gmail.com
Read more: http://geologistsrinivaskandi.webnode.com//

Seismic Geophysicist

WHAT YOU DO: Use computer simulations to look at how the Earth's surface moves over time, compare this with information from satellites to better understand the earthquake cycle, and use it to create disaster response products and plans.
EDUCATION: Depending on whether you want to teach at a college, go into industry, or work for a research lab, your educational path will be slightly different. Start with an undergraduate degree, usually in Earth Science; you'll need at least a master's degree if you want to teach, and to be a tenured professor at a research institution, a PhD. Strong background in math, physics, Earth science, and solid mechanics is also important.
USEFUL SKILLS: Computer programming, writing (for writing grant proposals), communication, and leadership skills.
How to get in: Working in labs as a student, publishing papers (as a part of a professor's or student's research team), and going to scientific meetings to network are all ways to get yourself out there and meet people that can help you. If you're interested in research, you'll need your name on as many publications as possible by the time you start looking for a job.
CAREER PATH: In industry or a research lab, getting an internship while in school then pursuing a job at any lab or related company will get your foot in the door. In academic positions, you'll start out as a researcher with some teaching responsibilities; after years of research and experience, you can become a professor with full tenure.
PAYBACK: For an academic researcher with a master's degree and 3-5 years of experience, the average salary is about $69,000. With a PhD, you'll make more. If you work in industry, you can work with a bachelor's or a master's and make anywhere from $40,000-$50,000, depending on degree and experience.
DOWNSIDES: Securing funding can be a challenge. You spend a good part of your time writing proposals to make sure that your research is paid for, so that you can continue working on what you love.
FUTURE OF JOB: Teaching positions at universities are becoming increasingly competitive, as are positions at research labs. Jobs in industry (oil, mining, geotechnical) vary, depending on the market, but can also be competitive depending on the economy and region.
NETWORKING:
Professional Societies:
American Geophysical UnionSeismological Society of AmericaGeological Society of America
Other Resources:
Southern California Earthquake Center (has student internships and other educational resources)
Jet Propulsion Laboratory (look on Education page, has lots of resources)
NASA (education page has resources)
US Geological Survey (has a bunch of educational resources)
EarthScience departments at universities/colleges
Produced, shot and edited for the National Science Foundation by instructors from the Gigniks program.
-Ali Sanford (LACES12th grade)

EU2017: FutureScience -- Rebroadcast—only $29: https://www.electricuniverse.live
BruceLeybourne’s presentation will examine the geometries of Earth’s electrical stellar transformer circuits. Both statistical data and geometric correlations suggest geophysical relationships between lightning and earthquakes. The basic “Delta-Y” electrical circuit geometry of the tetrahedron “fire element” is expanded to a little known geometric form that unifies the five Platonic solids. The unique example of a diminished trigonal trapezohedron can provide a simplified roadmap to electric influences on earth from space, with implications for our understanding of inline/collapsed vortex relationships of energy flow in living organisms. The surprising conclusion is that the same specialized geometry applies to both the human heart and the clockwork geo-plasma physics of co-rotating double layer phenomenon so essential to Electric Universe models.
Bruce has a Masters degree in Geology from the University of Southern Mississippi. He is a Registered ProfessionalGeologist and is currently ResearchDirector of Institute for Advanced Studies in Climate Change (IASCC), while also working with Geostream Consulting LLC and Climate-Stat Inc. to improve geophysical-weather models. Bruce has spoken at many international conferences on the topic of geophysics and climate, authored and co-authored many papers, and is currently organizing a book to share his views on the nature of climate change. In addition, he has spent 10 years offshore performing gravity and magnetic survey work onboard seismic exploration vessels, in addition to seafloor mapping, oceanography, and geophysics with the Naval Oceanographic Office. http://www.iascc.org/
If you see a CC with this video, it means that subtitles are available. To find out which ones, click on the GearIcon in the lower right area of the video box and click on “subtitles” in the drop-down box. Then click on the subtitle that you would like.
Become a Producer through the PATREON Rewards program -- https://www.patreon.com/tboltsproject
Subscribe to Thunderbolts Update newsletter: http://eepurl.com/ETy41
The ThunderboltsProjectHome: http://www.thunderbolts.info
EssentialGuide to the Electric Universe: http://www.thunderbolts.info/wp/eg-contents/
Facebook: http://www.facebook.com/thunderboltsproject
Twitter: @tboltsproject
Electric Universe by Wal Thornhill: http://www.holoscience.com/wp/
Electric Universe T-shirts and Gifts: http://stickmanonstone.com/
Copyrighted materials are being used according to the Multimedia Fair Use Guidelines.
The ideas expressed in videos presented on The Thunderbolts Project YouTube Channel do not necessarily express the views of T-Bolts GroupInc or The Thunderbolts Project(TM).

Seismic Surveying.mp4

This short animation was created for an exhibit in Fort Worth Texas. It shows how seismic vibrato trucks use vibrations to explore miles under the earth for oil. The animation was created in Modo 401, After Effects and Premier.

Background and release

After the success of her debut album, Let Go (2002), Lavigne released her second album, Under My Skin (2004), which debuted at number one in more than ten countries, went platinum within one month, and further established Lavigne as a pop icon. Later, a song that was co-written by Lavigne and ultimately cut from the final track list -- "Breakaway"—was later given to Kelly Clarkson, who used it as the title track and lead-off single for her Grammy-winning second album. In July 2006, Lavigne married Sum 41's Deryck Whibley and spent most of the year working on her third album, enlisting blink-182 drummer Travis Barker to play drums, and cherry-picking a variety of producers (including her husband) to helm the recording sessions. Lavigne described the album as "really fast, fun, young, bratty, aggressive, confident, cocky in a playful way."